Stuart Frye, Mission Systems Engineer Code 581 Software … · 2016-04-20 · Stuart Frye, Mission...
Transcript of Stuart Frye, Mission Systems Engineer Code 581 Software … · 2016-04-20 · Stuart Frye, Mission...
ALI False-Color Image, 2013 Fire in Australia
ALI True-Color Image, 2013 Bird Sanctuary in India
ALI False-Color Image, 2014 San Miguel Volcano
Hyperion (red) overlay on ALI Image (green), Oct 2012 Baltimore, MD 1
The EO-1 Team
Elizabeth Middleton
Daniel Madl
Stephen Ungar
Stuart Frye
Petya Campbell
Fred Huemmrich
David Landis
Lawrence Ong
Chris Neigh
Stuart Frye, Mission Systems EngineerCode 581 Software Systems Engineering Branch
April 14, 2016
https://ntrs.nasa.gov/search.jsp?R=20160005116 2020-07-07T18:55:59+00:00Z
EO-1 ALI complementing OLI. When the Villarrica Volcano
erupted, EO-1 was able to acquire an image on March 5,
2015 – five days before the next Landsat 8 overpass.
Landsat 8 OLIBefore Eruption
EO-1 ALIAfter
Eruption
MODIS, August 31, 2014
ALI natural-color composite August 27 overlaid with an infrared (IR) night view from September 1, 2014
EO-1 Complimenting Landsat 8 and MODIS
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EO-1 ALI night-time image of the Vatnajokull
volcano complementing MODIS (top).
EO-1 image of Wolf Volcano in Galapagos
Eruption on May 25th, image acquired on May 28th
EO-1 Image Gallery
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EO-1 ALI night-time image of Holuhraun Iceland
volcano
Hyperion Detects the California Methane Leak
On January 1, 2016, Hyperion imaged the massive methane leak in the Aliso Canyon region of California.
David Thompson’s (JPL) algorithm detected the methane leak within the Hyperion data and showed a pronounced
plume trending to the south. Since then, six additional acquisitions have been made, thanks to EO-1’s ability to rapidly schedule, reorient satellite attitude, and quickly
process and distribute the data.
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Hyperion Radiance Ratio (in-plume/out-of-plume)
Continuum removed
Imaging Spectroscopy measurements acquired December 29, 2015
Hyperion Matched Filter Detection Technique Provided byD. Thompson, A. Thorpe, R.O. Green and The Imaging Spectroscopy Team, JPL, CalTech
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Landsat 8 OLI2/14/2015
2016 Flooding on the Mississippi River
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EO-1 ALI1/12/2016
2016 Flooding on the Mississippi River
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Mission Operations, Science and Decommissioning TimelineBeginning Date
of Activity Duration Comments
Science Activities Selected Key Activities
Generate Level 2 Reflectance
10/1/16 1 year
Provided on demand, improvements for water and diverse terrain
Prototype Land Cover Products For HyspIRI, NASA TE, C Cycle and Climate Change, Bio-physical variables (Veg. fraction, pigments, LAI, moisture, Albedo)
Support NASA SLI and NEW Satellite Missions Data fusion and prototype products (ALI, Hyperion, Landsat, SENTINEL 2 MSI)
Spectral time series for VEGETATION targets FLUX sites, instrumented sites (e.g. SpecNet, LED), LTER, etc.
Spectral time series for CAL/VAL targets CEOS PICS, VIS/NIR sensor intercomparison
Disaster Response and Mitigation 12/31/16 Relief efforts- floods, hurricanes, fires, volcanoes
Decommissioning Timeline From receipt of termination notice to total close-out of EO-1 mission
Receive direction for NASA HQ to begin termination process flow 8/31/16 1 day Initial trigger to begin proposed steps below
Update End of Mission Plan & develop decommissioning plan 9/30/16 30 daysAs the mission is closer to a baseline EOMP, Final EOMP and Decommissioning Plan will require less time to be completed
Notification of Intent to Terminate is sent to Administrator with updated EOMP
10/1/16 1 dayPer NASA Policy Directive NPD8010.3B Notification of Intent to Decommission or Terminate Operating Space Systems and terminate Missions
Prepare for Decommission Review 11/15/16 45 days Days from Intent to Terminate Notification
Decommission Review 11/16/16 1 day This is KDP-F #1
HQ authorizes decommissioning & termination 11/23/16 5 days Allowing HQ to make decision 5 days following Decommissioning Review
Passivation Simulation and Rehearsals 12/15/16 25 days Days from Intent to Terminate Notification
EO-1 Key Decision Point – Phase F 12/15/16 30 days Days from Decommission Review
Wait a minimum of 90 days following Notification of Intent to Terminate 1/1/17 90 daysPer NASA Policy Directive NPD8010.3B Notification of Intent to Decommission or Terminate Operating Space Systems and terminate missions
Perform Pulse Plasma Thruster Test with all instruments ON to assess contamination
1/12/17 7 days Could consider performing prior to HQ authorization to decommission at KDP-F
Disposal Readiness Review 2/1/17 7 days This is KDP-F #2
Execute passivation activities 2/15/17 15 days See end of mission plan for details.
Decommission Ground System Hardware (Excess)
3/31/17 30 daysand Archive all documentation
Code 500 (TWIKI)
Facilities/Equipment Disposal
Contract/Agreement Modification and/or Closeout 4/1/17 30 days
EO-1 Operations and Science Documentation Closeout and Archive 4/1/17 180 days Upload to Wiki and meet National Archive requirements with DVD’s
Spacecraft Final Report 6/30/17 75 days Days from passivation completion
EO-1 Phase F Decommissioning Timeline
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Hyperion Lunar Trends
This figure shows the trending of the lunar calibration data over the mission duration. The plot shows that, except for the shortest wavelength in the VNIR focal plane ( :457.34), the Hyperion data are stable to within ± 1.5%. The data have been normalized to the first acquisition point, and are expressed as percent change from the beginning.
±1.5%
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-3
0
3
6
9
12
15
18
-85 -65 -45 -25 -5 15 35
Dif
fere
nce
fro
m R
oLO
[%]
Lunar Phase Angle [Degrees]
447.17
487.87
569.27
660.85
793.13
864.35
1245.36
1648.91
2213.93
Some bands show signs of phase angle dependencies, e.g. 569, 660, 793, 864 and 1648 nm.
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SUMMARY: The ROLO model provides a convenient avenue to conduct overall trending of instrument performance. But the ROLO model is unable to characterize individual detectors.
Comparisons with ROLO at Various Phase Angles
MODIS Aqua
LandsatSeaWIFSSeaWIFS
-7o EO-1
Change in EO-1 Equatorial Crossing Time
EO-1 ran out of orbital maintenance fuel in February 2011, when the Mean Local
Time (MLT) was 10:00 AM. Since then it has been drifting lower in orbit and earlier in overpass time. EO-1 will reach 8:00 AM MLT by October 2016.
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Jan-2012 Jan-2013 Jan-2014 Jan-2015 Jan-2016 Jan-2017 Jan-2018 Jan-2019 Jan-2020 Jan-2021
Solar Zenith Angle at EO-1 Overpass
Nominal 10:00 AMOverpass Time
2016
Lines represent SZA at overpass time for different latitude bands
SZA depends on overpass time, latitude, and date. The larger SZAs occurring in 2016 have already been experienced by EO-1 in previous years (at higher
latitudes and during winters).
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Solar Zenith Angle at EO-1 Overpass 40oN
For 40oN in 2016, approximately 60% of the time the SZA at EO-1 overpass time is within the previously experienced SZA range for that latitude.
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Nominal 10:00 AMOverpass Time
2016
EO-1 Flight Systems
• Health and Safety of spacecraft (S/C) and subsystems continuing nominal operations
• Power Systems are working nominally– After performing a cycle of VT changes to help condition
the battery for longer use (improves state of charge, speed of charge and differential voltage), the EO-1 VT is now set to a VT level of 4.5
• Instruments performing nominally– Solar and Lunar Calibrations routine including slow scan
Hyperion and a negative phase angle lunar calibration to aid Landsat-8 in calibration
• No Life Limiting items identified that would prohibit passivation
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EO-1 Mission Enhancements
• The EO-1 mission is out of usable fuel since February 2011 but attitude control system (ACS) fully functional – The spacecraft is no longer tasked to perform MLT
maintenance burns (inclination burns).
• With a transition from MOPSS (old) to ASPEN (new) and CMS (old) to SCP (new) mission planning systems, the FOT couldn’t initially perform Delta-V maneuvers.
• The FOT created procedures and implemented a way to perform Delta-V maneuvers on the new mission planning systems to perform debris avoidance maneuvers.
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EO-1 Mission Enhancements
• EO-1 Lunar Calibration Modifications– EO-1 FOT created a way to perform a single scan
Hyperion centered lunar calibration• This calibration is performed prior to a positive phase
nominal 4 scan lunar calibration with ALI and Hyperion
– Removed all atmospheric corrector (AC) commands and reduced the nominal 5 scan positive phase lunar calibration to a nominal 4 scan positive phase lunar calibration (removed all AC scans/commands).
– Conducted negative phase lunar calibrations in conjunction with Landsat-8
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EO-1 Debris Avoidance Maneuver
• The EO-1 spacecraft had a close approach with a (FENGYUN 1C DEB) on 5/10/2014 at 17:57:40 GMT
– Miss distance of ~167m
• The EO-1 FOT team worked with ESMO and CARA to plan and perform a 10 second Delta-V maneuver on 9 May 2014 at 13:30 GMT.
– The Burn was successful, the spacecraft thrusters fired for the full 10 seconds.
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EO-1 Recent Anomalies
• All Anomaly Reports available at https://eo1.gsfc.nasa.gov/
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EO-1 Orbital Information
• EO-1 Orbit Information on 03/13/15 00:00:00z
– Semi-major Axis = 7065.655 Km
– Eccentricity = 0.000545
– Inclination = 97.936 Deg
– RAAN = 338.705 Deg
– Argument of Perigee = 50.504 Deg
– True Anomaly = 137.525 Deg
– Altitude at Apogee = 691.366 Km
– Altitude at Perigee = 683.669 Km
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Earth Observing-1 Inclination Status for the MOWG
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• The ALI SNR is inherently 6 to 10X (~800%) that of ETM+.
• The ALI signal at 8 AM always exceeds 50% of the 10 AM.
• ALI SNR at 8 AM will be 3 to 5X better than that of ETM+ at
10 AM.
• EO-1 will not reach an 8 AM crossing time until October 2016.
Crossing Timeat Equator
March 22 June 22 September 22 December 22
Elevation (degrees)
cos(SZA)Elevation (degrees)
cos(SZA)Elevation (degrees)
cos(SZA)Elevation (degrees)
cos(SZA)
8:00 AM 28.3 0.47 26.9 0.45 31.8 0.53 27.7 0.46
8:30 AM 35.8 0.58 33.5 0.55 39.3 0.63 34.3 0.56
9:00 AM 43.8 0.69 40.1 0.64 54.3 0.81 40.8 0.65
9:30 AM 50.8 0.77 46.3 0.72 46.8 0.73 47.0 0.73
10:00 AM 58.3 0.85 52.3 0.79 61.8 0.88 52.9 0.80
12:00 PM 88.14 1.00 66.57 0.92 88.17 1.00 66.57 0.92
Signal@8 AMSignal@10 AM
0.56 0.57 0.60 0.58
ALI data taken at an 8 AM equatorial crossing timeis valuable in spite of the decline in SNR
Signal (i.e. solar irradiance) is a function of the cosine of the solar zenith angle (SZA).
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EO-1 Orbit Plots 5 Year Outlook Semi-Major Axis Altitude
(0.00 Feb 2016)
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EO-1 Orbit Plots 5 Year Outlook Apogee and Perigee Altitude
(0.00 = 1 Feb 2016)
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675
680
685
690
695
700
705
710
715
720
-90 -75 -60 -45 -30 -15 0 15 30 45 60 75 90
Alt
itu
de
Ab
ove
Ge
oid
(km
)
Latitude (deg)
EO-1 Altitude as a Function of Latitude(for the first orbit on January 4, 2015)
705 km "Circular" Orbit
EO-1 Descending Orbit
EO-1 Ascending Orbit
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S N
Descending (Day-time)
N to S
Ascending (Night-time)
S to N
Future NASA Budget Outlook• Full year of operations during FY2016 with
decommissioning starting October 2016 has been authorized
• Phase F report for decommissioning management starting October 2016 submitted to NASA Headquarters 31 March 2016
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Backup
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EO-1 New Ground Stations
– EO-1 Flight Operations Team (FOT), Earth Observing Systems (EOS) Data and Operations System (EDOS), Near Earth Networks Services (NENS), Universal Space Network (USN), and Wallops and White Sands scheduling personnel worked to switch from PF1/PF2 to Northern Alaska ground stations• testing of S-band uplink/downlink, X-band downlink, and telemetry
tracking for new ground stations in northern Alaska designated USAK-02/03/04
• coordination of firewall rule updates
• conducting test passes over the new ground stations
• implementation of modifications to the ground and flight software to point the satellite antenna at the correct locations
• analysis of the command link, telemetry receipt, science data capture, and ranging/tracking data files for operational readiness
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• The alternative way to understand and assess the stability of Hyperion is to perform a SBAF time series study. Figure shows the SBAF (OLI/S2) stability is better than 0.1% for last 12 years (except for blue band). This would also mean that constraint on simultaneous image pair based cross calibration can be relaxed
to take advantage of the long term stability of the site, The stability of Landsat 8 and Sentinel-2 reduces the impact of an eventual loss of Hyperion.
Helder, et al. 2015
The Long Term Stability of Hyperion
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